DE2346922A1 - AUTOMATIC VOLTAGE CONTROL DEVICE FOR A PHOTO MULTIPLE TUBE - Google Patents

Description

United States Atomic Energy Commission, Washington, D.C. 20545, UNITED STATES.

Automatic voltage control device for a photomultiplier tube.

The invention relates to an analytical photometer device, the one photomultiplier tube with associated Has power supply.

Over the past few years, the Oak Ridge National Laboratory's Molecular Anatomy (MAN) Program has been concerned with to develop analytical methods and automatic analysis systems for clinical laboratories. There are several Systems emerged, of which the GeMSAEC rapid analyzer was the most successful. This system is now used in Used in various clinical laboratories and uses centrifugal force to bring samples and reagents into one Bring together the multi-cuvette rotor, the mixture and

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Reaction can take place. A stationary photometer scans all cuvettes during the rotation and does so for each one The signal resulting from the cuvette is recorded and evaluated by an "on-line" computer, whereby the course from 15 to 42 Reactions can be observed during their occurrence.

Furthermore, a miniaturized GeMSAEC rapid analyzer was developed, to demonstrate the increased economy and reduced size for clinical applications. Such analysts are described in the report ORNL 4771 of May 1972. A GeMSAEC photometer is normally operated by the Samples and reagents are placed in the transfer disk and the solutions are moved into the cuvette zone. Of the a user using an oscilloscope adjusts the high voltage power supply for the photomultiplier tubes, which receives the transmission data signals. The photomultiplier tube voltage is increased until "the pulse height for cuvette no. 1 (which is normally pure water) is in the range of 9-9.5 volts. This process typically takes 15 to 30 seconds, after which the data can be recorded. the commercially available photometers operate in the same manner.

A problem with such a design is that the user can overload and saturate the photomultiplier tubes, the tube can also burn out. For many applications, however, the absence of any is even more unpleasant Feedback in the system. When the high voltage power supply to the photomultiplier changes, or what more often occurs when the gain of the photomultiplier tubes changes, there is no automatic compensation. Consequently all data values contain an error corresponding to the size of the unknown gain or the voltage change. If a minicomputer is used, this problem does not occur because the computer uses cuvette no. can relate. If, however, a simplified system is desired, it would be useful to activate the pure water signal

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to maintain a specified voltage value, independently of the change in high voltage and photo multiplier amplification. If one did this, the data signals from other cuvettes would remain constant. The water output signal could maintained at the desired fixed voltage if means could be provided to power the photomultiplier high voltage supply to regulate or control when this is related to the water signal. The present invention brings satisfaction for the needs mentioned.

The present invention seeks to provide a system for the pure water output signal amplitude from a GeMSAEC to be analytical To keep the photometer constant during its operation.

For this purpose, the invention provides a feedback circuit, which the amplitude of the water cuvette output signal of the above photometer probes, through a fast-acting solid-state switch. This device ensures that the Water signal amplitude remains constant by controlling the high voltage supply to the photomultiplier tube, and following a comparison of the pure water transmission signal with a very well controlled reference voltage.

Further advantages, objects and details of the invention result from the description of an embodiment with reference to the drawing; in the drawing is a schematic circuit diagram of the system according to the invention for controlling the input variable for the high voltage supply of a photomultiplier an analytical photometer.

The present invention can be used in conjunction with the GeMSAEC analytical Photometer system can be used, which in US patent 3 555 284 of January 12, 1971, with the previously mentioned miniaturized system or with any other similar analytical photometer system.

To the pure water output signal (in the following also abbreviated water output signal called) by an analytical photometer system

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to hold on to a fixed tension, should the pure or The cuvette containing clear water must be scanned, i.e. interrogated, with each rotation of the rotor. This is now according to the present invention by using fast-acting solid-state switches possible. The feedback loop shown in the drawing brings the first cuvette (which contains the clear water) - which is not shown in the drawing - onto its desired output voltage within 3 seconds and holds it at this value for the duration of the test run.

The fast working ones used in the system in the drawing Solid state switches 15 and 16 are from Teledyne, respectively Relays, 3155 W. El Segundo Boulevard, Hawthorne, California 90250 and named "Model 640-1 Sera DIP Solid State SPST Relay ". Each of these units is a complete solid-state replacement for reed relays; these solid-state relays have a low noise level, a low contact resistance, switch without jumping and have switching speeds of up to 100 KHz.

Those coming from the photomultiplier tubes of a photometer system Transmission data signals - see the drawing are fed to the input of a solid-state switch 16. One reference voltage coming from a well regulated power supply 13 and a potentiometer 14 is applied to the input of the Solid-state switch 15 applied. When the peak of the first cuvette voltage (containing clear water) is generated the rotor, not shown, of the photometer system sends a key or gate signal (new sample pulse) of approximately 5 volts to the Switches 15 and 16 to bring them into the on-state. Of the The resistance of these switches quickly goes to zero, which allows the voltage values at the inputs to pass through. The tactile impulse will result in the normal high resistance state in switches 15 and 16 after going back to zero. the Voltage from supply 13 and potentiometer 14 corresponds the 9 volts desired for cuvette no. 1 and is applied to an inverter 21 by means of a touch and hold unit 17. The actual voltage of cuvette # 1 (pure water)

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is applied to the same inverter 21 through a Peak follower and hold unit 18, although this voltage has opposite polarity to the reference voltage of unit 17.

The resulting signal for the inverter 21 is then from

the
such a direction that / from the photomultiplier

, coming tension
voltage supply / is corrected if the first cuvette pulse differs from the reference voltage derived from the power supply 13.

The inverter 21, for example, a negative gain of 1/10, generates the correct polarity for the three operating mode control device 23. A diode 22 is bridged the inverter 21 as a feedback, so that the inverter only in works in a direction that requires additional tension. This prevents a reset capacitor in the Control device 23 is charged in the opposite direction. The potentiometer high voltage supply 13, 14 is always

the positive; it never becomes negative, so / the diode 22 on the inverter does not allow the controller reset capacitor to charge in the opposite direction when the Controller voltage becomes zero. The three modes of operation of the controller 23 are as follows: 1) rate, 2) proportional, and 3) provision. For a general discussion of a typical three-mode controller, refer to the following Article referenced: "Automatic Controller Action" in "Instruments And Control Systems" magazine, December 1971, Pages 235-244. The output of the control device 23 is through a conductor 28 with a control transistor 27 in the input circuit connected to the existing photomultiplier high voltage supply. In this way, the controller 23 operates as a variable bias voltage for transistor 27 so that the photomultiplier high voltage supply regulates as needed is used to keep the water output from the photometer system at a desired constant value, even if photomultiplier gain changes or a change in power supply occurs during photometer operation. In this way, automatic restoration of the photometer data transmission signals to their correct values is obtained.

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In the circuit shown in the drawing are some safety measures intended. For example, there is no need for high voltage on the photomultiplier tube when the transmission lamp of the photometer system is off. Otherwise it would the circuit would bring the photomultiplier supply to its maximum voltage and then, when the lamp would turn on, the photomultiplier tube would saturate and burn out. Likewise, it should be when the rotor is stopped becomes, the three-mode controller does not output any signal. In addition, if filters for the Transmission pulses of the photometer system are changed, no control signal is sent to the photomultiplier supply. Switches 24, 25 and 26 effect these safety measures. Each switch is electrical via the feedback of the controller 23 is switched on and brings the output variable of the control device to zero in the closed state, which in turn drops the photomultiplier supply to zero.

Another safety measure, not shown, can be added to the above circuit - if desired. This additional Measure is a comparison device for closing a solid-state switch located above the control device feedback when any transmission pulse reaches the maximum Exceeds the voltage level in the system (the water signal level of 9 volts). An error signal of this kind is then possible when the rotor suddenly stops or loses speed, as the amount of light received by the photomultiplier tube decreases Is a function of rotor speed.

It should be noted that the present invention can be used in the same way in other fields of application.

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Claims (2)

" ⁷ " 7346922 PATENT CLAIMS γ 1 Λ Analytical photometer device with one several cuvettes - Having multi-cuvette rotor for receiving samples and reagents to be mixed and brought into reaction, wherein Means are provided to rotate the rotor at a desired selected high speed, wherein a stationary photometer system for scanning all cuvettes during the rotor rotation, at least one of the Cuvettes containing pure water to provide an output for reference purposes and also being an "on-line" computer is connected to the output of the photometer system, to evaluate the signal received from each of the cuvettes during the operation of the system, and finally the photometer system a photomultiplier tube and a source of photomultiplier high voltage supply by a feedback circuit to maintain the pure water cuvette output voltage signal at a desired constant value during operation of the photometer system, wherein the feedback circuit has a first fast acting solid state switch (15) and a second fast acting solid state switch (16), a well regulated power supply (13), one between the output of the regulated power supply and the first switch have a potentiometer for applying a desired reference voltage thereto, which corresponds to the desired pure water output voltage signal, the output of the photomultiplier tube with the second switch is connected and means are connected to the two switches in order to switch them to the on-state switch, in sequence to the rotor position and at the moment when the pure water output signal from the photometer system is at its peak value, and wherein further a key and hold unit (17) with the output of the first switch (15) and a tip following and holding unit (18) is connected to the output of the second switch (16), and that in turn an output variable is generated which has a polarity opposite to the output variable of the key and hold 409814/1116 - 8 - 7346922 unit, with an inverter (21) being provided and circuit means for the signal output variables of the touch and hold unit and the peak follower and hold unit combine and this combined output signal as an input the inverter, and wherein a diode (22) is provided as a feedback across the inverter, and a three-mode controller (23) is at the output of this inverter, with a control transistor (27) connected to the input circuit the photomultiplier high voltage supply is connected, and further wherein circuit means (28) include the output of the control device connect to the control transistor, whereby the feedback circuit has the water output voltage signal on a holds the desired constant value even if the photomultiplier gain changes or the power supply changes changes during operation of the photometer system. 2. Apparatus according to claim!, Characterized in that the The feedback circuit also contains at least three safety control circuits that operate in parallel as feedback across the Control device lie, each of these switches, when it is closed, the output of the control device brings to zero, which in turn the photomultiplier supply brings to zero, through the aforementioned control transistor, and furthermore each of the safety control switches can be brought into a closed position as a result of the corresponding operating conditions of the photometer system, during a time when high voltage is not required on the photomultiplier tube. U 0 9 8 U / 1 1 1 6